Vibrating beam transducer



Dec. 30, 1969 Original Filed Jan. 4. 1965 I H. E RIORDAN I I VIBRATING BEAM TRANSDUCER 5 Sheets-Sheet 1 HUGH E. RIORDAN INVENTOR.

BYM-p ATTORNEY H. .E. mbR'pAN '3,486;383

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ATTORNEY so, 1969- 1mm 3 6,383 7 VIB-RATING BEAM TRANDUcE' Original Filed Jan. 4; 1965 S'Sheets-Sheet s l-UGH E RlOFDAN mvmron N'DRNEY Dec. 30, 1969 E, RIORDAN 3,486,383

VIBRATING BEAM TRANSDUCER Original Filed Jan. 4, 1965 5 Sheets-Sheet 5 l 1&8 \204 212 FIG. 9 FIG. 10

204 204 204 204' F H 252 246 240 24s 254 242 ///////4 238 FIG. 11

HUGH E. RIORDAN INVENTOR.

AT TORNEY United States Patent C) 3,486,383 VIBRATING BEAM TRANSDUCER Hugh E. Riordan, Wyckoif, N.J., assignor to Singer-General Precision, Inc., Little Falls, N.J., a corporation of Delaware Original application Jan. 4, 1965, Ser. No. 423,148, now Patent No. 3,413,859, dated Dec. 3, 1968. Divided and this application Aug. 24, 1967, Ser. No. 672,665

Int. Cl. G01p 15/08 US. Cl. 73-517 2 Claims ABSTRACT OF THE DISCLOSURE A vibrating beam transducer providing a direct digital output for a gyro. A pair of vibrating beams are housed in an elongated container. Connection to one of the gyro gimbals is made either from a center point connecting two near ends of the beams to the gimbal or by a frame extending over the elongated container to the outer ends of the beams.

This is a division of application Ser. No. 423,148 filed Jan. 4, 1965, now Patent No. 3,413,859 issued on Dec. 3, 1968.

The present invention relates to gyros and more particularly to a rate gyro having a digital output.

There presently are two broad application areas for a gyro with a digital or pulse output; namely, in advanced autopilots for vehicles carrying a central high-speed digital computer, and in strap down guidance systems. These applications possibly could be satisfied by employing gyros having torquers and pick-offs capable of being used in an electrically restrained rate mode, in conjunction with pulse rebalance circuits, (or analog capture) and voltage to frequency converters. However, the electrical capture scheme requires excessively complex circuitry and very high torquer output which result in high cost and compromised gyro performance. Direct encoding of gyro output using a digital angle encoder also might be considered, but this is not practical because the large gyro output angles required for reasonable resolution would result in poor bandpass and excessive cross coupling.

In accordance with the present invention a rate gyro having a direct digital output is provided which eliminates the disadvantage of the other approaches mentioned above. The direct digital output is obtained by using vibrating beam force transducers similar to the type employed in advanced digital accelerometers to restrain precession of the gyro rotor. Because of the high stiffness-scale factor product of the transducers, output angles can be limited to a few microradians, if desired, and correspondingly broad bandpass and wide dynamic range can be obtained. The supporting electronics is relatively simple and the output is a frequency proportional to input angular rate. Precise input angle information is available in digital form from a simple count of output cycles.

Accordingly it is one object of the invention to provide a gyro which produces a direct digital output.

It is another object of the invention to :provide a gyro which does not require torquers or angle pick-offs.

It is a further object of the invention to provide a rate gyro having a direct digital output which enables extremely wide bandpass to be obtained.

It is a still further object of the invention to provide a gyro of the type described above wherein the angular precession of the gyro is infinitesimal so that no significant cross coupling or rectification errors can occur.

It is a still further object of the invention to provide a digital transducer which can be incorporated in existing ice gyro designs with minor modifications to convert the gyro output to a direct digital output.

It is a still further object to provide an evacuated vibrating beam transducer capsule which can be incorporated easily in a gyro operating in gas or air to convert the gyro output to a digital output.

Other objects and features of novelty of the present invention will be specifically pointed out or will otherwise become apparent when referring, for'a better understanding=of the invention, to the following description taken in conjunction with the accompanying drawings, wherein:

FIG. 1 is a perspective view of a conventional gyro incorporating a vibrating beam transducer in accordance with one embodiment of the invention for producing a digital output;

FIG. 2 is a perspective view of the vibrating beam transducer used in the gyro of FIG. 1;

FIG. 3 is a fragmentary view illustrating a modified construction for connecting the vibrating beam transducer of FIG. 1 to the gyro gimbal;

FIG. 4 is a fragmentary view illustrating another modified construction for connecting a pair of vibrating beam transducers between the gyro frame and gimbal in a push pull relationship;

FIG. 5 is a schematic diagram of a circuit for vibrating the transducers of FIG. 4 and producing a digital out- P FIG. 6 is a perspective view of a two-degree-of-freedom gyro restrained by a pair of vibrating beam transducers;

FIG. 7 is a perspective view similar to that of FIG. 6 illustrating a two-degree-of-freedom gyro restrained by four vibrating beam transducers;

FIG. 8 is a cross-sectional view of a two-degree-of-free dom gyro illustrating another embodiment of the invention;

FIG. 9 is a sectional view of a vibrating beam transducer capsule embodying features of the invention;

FIG. 10 is a sectional view similar to that of FIG. 9 illustrating another embodiment of a vibrating beam transducer capsule; and,

FIG. 11 is a sectional view illustrating still another embodiment of a vibrating beam transducer capsule.

-Referring to FIG. 1, a conventional gyro 10 is illustrated which has been modified to produce a digital output directly in accordance with the present invention. It comprises a gimbal 12 having axially aligned stub shafts 14 and 16 journalled in the upstanding legs of a frame 18 by gimbal bearings 20 and 22, respectively. A conventional grease ring damper 24 is mounted on the frame and operatively connected to the stub shaft 16 to dampen movement of the gimbal 12 in a conventional manner. A rotor housing 26 is mounted within the gimbal 12in a conventional manner with the rotor spin axis 28 perpendicular to the precession axis 30 and input axis 32 of the gyro. The gimbal 12 is restrained against significant angular movement relative to the frame by a vibrating beam transducer 34 connected between a flange 36 of the frame and a rigid finger 38 projecting from the gimbal 12.

The vibrating beam transducer 34 is of the type employed in advanced digital accelerometers as disclosed in Patent No. 3,269,192, entitled Tuning Fork Digital Accelerometer by Hamilton Southworth, Jr. and John C. Stiles and assigned to the assignee of the present application. Referring to FIG. 2 as well as FIG. 1, the vibrating beam transducer 34 comprises parallel spaced apart beams 40 and 42 connected together in parallel spaced apart relation by end supports 44 and 46. The vibrating beam transducer is mounted on the gyro by attaching the end support 44 to the projection 38 on the gimbal and attaching the end support 46 to the flange 36 on the frame.

Details of the construction of the vibrating beam transducer and the manner in which the beams 40 and 42 are vibrated at their natural frequency to produce the digital output will be described in greater detail hereinafter. In general, however, the vibrating beam transducer has sufficient stiffness to limit precession of the gimbal 12 in either direction to a very small angle, such as a few microradians, if desired. When the gimbal precesses in a clockwise direction as viewed in FIG. 1 the vibrating beam transducer is placed under compression, and when the gimbal rotates in a counter-clockwise direction the vibrating beam transducer is placed under tension. The natural frequency of vibration of the beams 40 and 42 decreases in proportion to an input angular rate which places the vibrating beam transducer in compression, and increases in proportion to an input angular rate which places the vibrating beam transducer in tension. This change in natural frequency is proportional to the input angular rate and is utilized to produce the desired digital output.

Modifications of the gyro illustrated in FIG. 1 are shown in FIGS. 3 and 4. In FIG. 3 the end support 44 of the vibrating beam transducer 34 is connected to the gimbal 12 by a spring section 50 rather than by the rigid projection 38 illustrated in FIG. 1. The other end support 46 is connected directly to the flange 36 of the frame 18 as before. This reduces the restraint on the gimbal and allows it to process through a slightly greater angle. In FIG. 4 a second vibrating beam 35 is connected between a flange 37 on the frame 18 and the projection 38 to which the vibrating beam transducer 34 is connected. The arrangement is such that the vibrating beam transducer 34 is placed under compression and the vibrating beam transducer 35 placed under tension when the gimbal 12 precesses in a clockwise direction and the transducer 35 compressed and transducer 34 tensioned when the gimbal precesses in a counter-clockwise direction. The gyro output is taken as the difference frequency of both transducers to cancel the even-order non-linear terms. This modification provides extremely good linearity.

The aforementioned Patent No. 3,269,192, assigned to the assignee of the present application discloses several techniques for vibrating the beams (or tines) of transducers similar to the transducer 34 of the present invention, together with techniques for monitoring the vibrations and producing a digital output. In accordance with one of these techniques, the beams 40 and 42 of each of the transducers 34 and 35 (FIG. 4) are made of a very thin beam of magnetic permeable material so that they can be vibrated at their natural frequency by solenoids 51-54 energized by an AC voltage. In this embodiment the beams 40 and 42 each have a length inch, a width w= A inch, and a thickness h=.003 inch.

As illustrated in FIG. 4 the solenoids 51 and 52 are positioned on opposite sides of the vibrating beam transducer 34 and the solenoids 53 and 54 on opposite sides of the transducer 35. A pair of interconnected pick-up coils 55 and 56 are positioned in the air gaps between the solenoids 51 and 52 and the vibrating beam transducer 34 and a similar pair of interconnected pick-up coils 57 and 58 are positioned in the air gaps between the solenoids 53 and 54 and the vibrating beam transducer 35 so that each of the pick-up coils will have a voltage induced therein having the same frequency as that of the vibrating beam adjacent thereto. Changes in the natural frequency of the vibrating beams when placed under compression or tension, as previously described, will be detected by the pick-up coils 55-58 and the output of the pick-up coils may be applied to a suitable circuit, such as the circuit illustrated in FIG. 5, to indicate the magnitude of the input angular rate. The signal from the pick-up coils 55-58 also is fed back to the solenoids 51-54 to control the frequency of the energizing voltage to maintain the beams vibrating at their natural frequency.

Referring specifically to FIG. 5, one embodiment of an electrical circuit is illustrated for vibrating and monitoring the vibrating beam transducers 34 and 35 of FIG. 4. The AC voltage induced in the pick-up coils 55 and 56 is amplified by the amplifier 280 and applied to the solenoids 51 and 52 to sustain the vibration of the beams 40 and 42 at their natural frequency. The amplified voltage has a frequency W and is applied to a frequency multiplier 282 and then to a mixer 284. An identical feedback circuit (not shown) incorporating the pick-up coils 57 and 58 and the solenoids 53 and 54 is provided to sustain the vibration of the beams of the vibrating beam transducer 35 and an amplified voltage having the frequency W is similarly applied to a frequency multiplier 286 and then to the mixer 284 where it is mixed with the frequency W The intermodulation of the frequencies W and W that occurs in the mixer 284 produces the sum and difference frequencies W +W and W W which, after separation by filters 288 and 290, are applied to counters 292 and 294, respectively. The counters convert these frequencies into proportional digital numbers which are then multiplied in a digital multiplier 296 to produce the integral of the input angular rate as a digital number. The interval over which this takes place is determined by the length of the gate voltage produced by a generator 298 which opens the gate 300 admitting the output frequencies of the mixer to the counters 292 and 294. The generation of the gate voltage is controlled by a trigger pulse which also is applied as a reset pulse to the two counters. The pulse is delayed before application to the gate voltage generator in order to allow resetting of the counters to be completed before a new computing period is initiated.

As stated previously precession of the rotor 26 mounted Within the gimbal 12 places both beams of one of the vibrating beam transducers 34 under compression and both beams of the other transducer under tension. This causes a decrease in the natural frequency of the vibrating beam transducer placed under compression which is proportional to the input angular rate and an increase in the natural frequency of the vibrating beam transducer which is placed under tension which also is proportional to the input angular rate. By arranging the two vibrating beam transducers 34 and 35 in back to back relationship as illustrated in FIG. 4 so that the natural frequency of one is increased while that of the other is decreased in response to the input angular rate, temperature sensitivity is reduced and the two outputs from the vibrating beam transducers may be combined in a very simple way to produce the frequency output with errors minimized as previously stated. If only one vibrating beam transducer 34 is employed as illustrated in FIG. 1 its frequency output can be compared with a timing reference in the digital computer to determine in its natural frequency in response to the input angular rate.

Another technique disclosed in the aforementioned copending application for vibrating a transducer similar to the vibrating beam transducer 34 at its natural frequency and monitoring the frequency of vibration is to vibrate the beams 40 and 42 of the transducer electrostatically by passing an AC current therethrough. The beams are preferably made from quartz crystals lapped down to a thickness of .003 inch, with each of the confronting surfaces thereof gold-plated and wired at one end with a 5- mil wire to facilitate electrical connection to the beam. The end supports 44 and 46 preferably are made of quartz to electrically insulate the beams from one another and from the gyro gimbal and frame. The beams 40 and 42 are connected to the end supports by a suitable cement, such as a watch crystal cement which may be dissolved by acetone. The end supports, in turn, are cemented to the projections 38 and flanges 36 and 37 of the frame (FIG. 4) and, if desired, clamps may be provided to firmly secure the end supports to the projection 38 and flanges 36 and 37.

In the particular embodiment illustrated in FIGS. 1 and 2, the length l of the beams is about one-fourth of an inch, and the width w of each is one-sixteenth of an inch, with the clearance between the beams being about .007 inch. To provide beam amplitudes of about 10,11. inches, an AC voltage of 40 volts may be impressed across the beams or a DC bias voltage of 40 volts may be impressed across the beams, along with an AC voltage of volts. Voltage frequencies of from 4-8 kc. or more may be used, and the natural frequency of the beams picked up or monitored in any suitable manner, including accoustically, if desired. Circuitry similar to that illustrated in FIG. 5 may be employed to convert the input angular rate of the gyro to digital form and also to provide a feedback circuit for varying the frequency of the voltage applied to the beams to maintain the vibration of the beams at their natural frequency.

Referring to FIG. 6 a conventional two-degree-of-freedorn free gyro 60 is illustrated which is equipped with two vibrating beam transducers 62 and 64 to provide digital outputs. The gyro 60 comprises a frame 61 having a gimbal 66 rotatably mounted thereon by gimbal bearings 68 and 70 with a rotor housing 72 rotatably mounted within the gimbal 66 by gimbal bearings 74 and 76. The rotor spin axis 73 is, of course, perpendicular to the output axes defined by the gimbal bearings. The vibrating beam transducer 62 is connected between the rotor and frame to restrain precession about the axis defined by the gimbal bearings 74 and 76, and the transducer 64 is connected between the rotor and frame to restrain precession about the output axis defined by the gimbal bearings 68 and 70. Consequently, the output frequency of the vibrating beam transducer 62 can be utilized to provide a digital output representative of the input angular rate about one input axis and the frequency of the vibrating beam transducer 64 utilized to produce a digital output proportional to the input angular rate about theother input axis. In this embodiment the vibrating beam transducers 62 and 64 are identical to the transducer 34 of FIGS. 1 and 2, but are connected to the frame 64 and rotor 72 by flexure wires 78 to accommodate misalignments due to tolerances, deflections and differential thermal expansion.

Referring to FIG. 7 the gyro 60 of FIG. 6 is illustrated with vibrating beam transducers 82 and 84 added to assist the vibrating beam transducers 62 and 64. The vibrating beam transducers 82 and 84 are connected between the rotor housing 72 and the frame 61 by flexure pivots 78 with the transducer 82 diametrically opposite the transducer 62 and the transducer 84 diametrically opposed to the transducer 64. This arrangement is analagous to the embodiment of FIG. 4 in that one transducer of each diametrically opposed pair will be placed in compression when the other is placed in tension and vice versa so that the output about each output axis will be the difference frequency. As in FIG. 4 this cancels the evenorder non-linear terms and improves linearity.

Referring to FIG. 8, a two-axis rate gyro 100 is illustrated having a combination flexure wire and diaphragm in place of the conventional gyro gimbal structure. The gyro 100 comprises a base plate 102 having a central opening 104. A central support 106 is mounted on the base plate 102 above the central opening 104. The central support 106 has a radially projecting flange 108 on the upper end thereof terminating in a cylindrical flange 110. The transducer electronics is contained in a package 112 positioned within the central support 106 so that electrical connections can be made thereto through the opening 104.

The rotor 114 is contained within a rotor housing 116 which comprises a supporting body 118 and a windage shield 120. The body 118 comprises an inverted cupshaped portion 122 positioned over the central support 106 having a radial flange 124 projecting from the lower end thereof to which the windage shield is secured. A cylindrical bearing wall 126 projects upwardly from a central dividing wall 128 of the body 118 in coaxial alignment with the central opening 104 of the base plate 102.

A pair of spin bearings 130 and 132 are cemented within the bearing wall 126 for rotatably journalling a stub'shaft 134 projecting downwardly from an upper end wall 136 of the rotor 114. The rotor has a cylindrical wall -138 "depending downwardly from the end wall 136 which is: maintained in spaced relation to the radial flange 124 of the supporting body by a shoulder 140 on the central stub shaft 134 engaging the upper spin bearing 130, the upper spin bearing being maintained in spaced relation to the lower spin bearing 132 by a pair of concentric spacer sleeves 142 and 144. A hysteresis ring 146 is mounted on the cylindrical wall 138 between the spin bearings 130 and 132 and a motor stator 148 within the hysteresis ring 146 is mounted on the bearing wall 126 of the supporting body 118. Suitable stator coils 150 are wound on the stator 148.

The supporting body 118 is universally mounted on the central support 106 by a flexure wire and a flexure diaphragm 162, the latter being connected between the upper end of the cylindrical flange 110 and the end face of a boss 164 on the lower face of the dividing wall 128. The flexure wire 160 takes axial load and the diaphragm 164 provides the radial load capacity. Fingers and 172 are fixed to the radial flange 124 of the support body 118 and project radially inward therefrom along one output axis of the gyro. A vibrating beam transducer 173 is connected between the finger 170 and the radial flange 108 of the central support 106 and a vibrating beam transducer 174 is connected between the finger 172 and the radial flange 108. A second pair of fingers (not shown) are similarly positioned on the other output axis and fixed to the radial flange 124 in position to cooperate with the radial flange 108 to support another pair of vibrating beam transducers in a similar manner to restrain precession of the gyro about the other output axls.

As in the embodiment of FIG. 7 the difference frequency of the vibrating beam transducers 173 and 174 provides the output about one output axis and the difference frequency of the other pair of vibrating beam transducers (not shown) provides the output about the other output axis. The entire gyro is enclosed by a cover secured to the base plate 102 and, if high performance is required, the entire unit can be evacuated since the transducers preferably are operated in a vacuum. However, for applications of moderate accuracy, operation in air or gas is acceptable.

An inertial grade gyro can be made by enclosing the vibrating beam transducer or transducers in a suitable evacuated container which incorporates a flexible force transmitting element. The transducer, so enclosed, is used to restrain the rotation of a float in a fluid-filled gyro, for example. The flotation of course isolates the sensitive elements of such an instrument against environmental accelerations. Three types of transducer capsules which can be used are illustrated in FIGS. 9, l0 and 11. In each case the critical requirements, in addition to perfect leak tightness, are minimum spring rate of the flexible seal element and insensitivity to ambient pressure changes.

Referring to FIG. 9, a simplified transducer capsule comprises a container 184 having a solid wall 186, end walls 188, an apertured wall and a central boss 192 having a radial flange 194 on the outer end thereof defining a central opening coaxially aligned with the aperture in the wall 190. One end of a thin walled, small diameter tube 196 having a circular cross-section is fixed within radial flange 194 and the other end thereof is closed by a fitting 198. A pair of vibrating beam transducers 200 and 202 are fixed between the fitting 198 and opposed points on the end walls 188 by flexure wires 204. An input lever 206 extends into the tube 196 with one end thereof fixed to the fitting 198 and the other end thereof adapted to be fixed to the inertial element of the gyro to provide the input torque to the vibrating beam transducers as indicated by the curved arrow. One of the transducers is placed in compression and the other in tension in response to precession of the inertial element in one direction and this is reversed in response to precession in the other direction. The necessary pivotal movement of the lever 206 is accommodated by bending of the thin walled tube 196. If the motion is sufficiently small the tube will retain its circular cross-section and changes in ambient pressure will not impose any forces on the vibrating beam transducers. The container 184 is evacuated.

Referring to FIG. 10 another embodiment is illustrated for transmitting the gyro output torque from a fluid-filled gyro float chamber into an evacuated transducer container. This embodiment comprises a sealed container 210 having end walls 212 sealed by a diaphragm 214. A lever 215 is sealingly supported on the diaphragm 214 with one end thereof projecting into the sealed container. A pair of vibrating beam transducers 216 and 218 are connected between the end of the lever within the container and opposed points on the end walls 212 by flexure wires as in the embodiment of FIG. 9. A flexure wire 220 is connected between the inner end of the lever 215 and a wall 222 of the container to resist axial pressure loads on the diaphragm.

The container 210 is evacuated as in the embodiment of FIG. 9 and, therefore, this construction is pressure sensitive in the sense that the bending stiffness of the diaphragm 214 is a function of the pressure differential across it. However, the pressure sensitivity function has zero slope at zero angular deflection, so that for small motions, good independence of pressure change can be achieved. The input force is applied in either of two directions as indicated by the arrow and the diaphragm bends about an axis in its plane so as to act as a pivot fulcrum.

Referring to FIG. 11 another embodiment of a transducer capsule is illustrated. It comprises a rigid frame 230 having end flanges 234 and 236. A sealed container 238 is positioned between the end flanges 234 and 236 which is divided into two separate compartments by a central wall 240. The outer ends of the compartments are sealed by flexible diaphragms 242 and 244 and the compartments are evacuated. Vibrating beam transducers 246 and 248 are supported in each of the compartments by flexure wires 204 and additional fiexure wires 252 and 254 connect the diaphragms 242 and 244 to the flanges 234 and 236, respectively. Relative movement between the frame 230 and sealed container 238 in the direction indicated by the arrows produced by the inertial element being restrained, places one transducer in compression and the other in tension as in the previous embodiments and the output is taken as the difference frequency of the transducers.

The following primary formulas have been derived for calculating various parameters of the vibrating beam transducers, and gyros employing these transducers. In these formulas l, w and h represent the length, width and thickness of a vibrating beam as illustrated in FIG. 2 and the following symbols are employed:

' is the stress in a beam in pounds per square inch;

F is force in pounds;

E is Youngs modulus (p.s.i.);

A is frequency change;

f is the unloaded base frequency of the beams;

", is the mass density of the beam material in 1b. secP/infi; E; is the base frequency instability (c.p.s.);

K' is the fixed constant independent of beam design.

vibrating beam transducer as illustrated in FIG. 1:

( 7 Fr H (,2;

therefore where:

H is angular momentum (inch lb. sec.);

t is input angular rate (rad/sec.); r is the perpendicular distance from the precession axis 30 to the vibrating beam transducer 34.

The basic Equations 1 through 6 now become, for a gyro:

where: ip is the angular rate bias uncertainty.

ANGLE RESOLUTION fosa GYRO NATURAL FREQUENCY I? T (17 k E 2H 1 d E E W ZHETZ 2HEr 1'1 J Jl v 1 where: gfyjij k is the axial spring rate of a pair of beams; J is the output axis moment of inertia of the gyro (in. 1b.

While it will be apparent that the embodiments of the invention herein disclosed are well calculated to fulfill the objects of the invention, it will be appreciated that the invention is susceptible to modification, variation and change without departing from the proper scope of fair meaning of the subjoined claims. For example, other types of vibrating transducers can be employed in place of the vibrating beam transducers disclosed herein. The aforementioned copending application of Hamilton Southworth, Jr. and John C. Stiles discloses several different types of vibrating transducers which could be employed. Also vibrating strings of the type disclosed in the patent to Appleton 3,098,388 issued on July 23, 1963 could be employed in place of the vibrating beam transducers. Since the vibrating strings collapse when compressed, they would have to be used in back-to-back relationship with both strings pre-tensioned. Referring to FIG. 4, for example, a vibrating string could be substituted for each of the vibrating beam transducers 34 and 35 and pretensioned in the null position. With this arrangement the tension in one spring would increase and the tension in the other decrease in response to precession of the gimbal 12 in one direction, and this would be reversed in response to precession in the other direction. Of course, the natural frequency of the strings increases when the tension increases and decreases when the tension decreases. For some applications it also would be possible to restrain precession with force transducers, such as piezo-electric crystals, which are not vibrated. Such force transducers would produce an electrical output which varies with the force exerted on the transducer in response to precession of the gyro rotor.

Accordingly the term vibrating beam transducer is used in the following claims to define transducers which can be compressed as well as tensioned. The term vibrating transducer is used to generically designate vibrating [beam transducers and other types of transducers which are vibrated, such as vibrating string transducers. The term transducer is used in the following claims to generically define all vibrating and non-vibraing transducers which can be used to convert a force applied thereto by precession of the gyro rotor into an electrical output signal which varies in response to the applied force.

What is claimed is:

1. A vibrating beam transducer capsule comprising an elongated container (184) extending in a plane having a central opening therein, a thin walled small diameter tube (196) disposed normal to said plane having one end sealed Within said opening and the other end projecting freely into said container, a fitting (198) sealing off said other end of the tube so that said container can be evacuated, a pair of vibrating beam transducers (200, 202) each having one end connected to said other end of said tube and the other end connected to the wall of said container by flexure wires (204); an input lever (206) extending into said tube (196) and having one end thereof connected to said fitting (198) for transmitting torque thereto, the other end of said lever being adapted to be fixed to a gyro in a manner to pivot said one end of the lever in response to precession of the gyro rotor, one of said transducers being placed under compression and the other under tension in response to precession of the gyro rotor in one direction and said one transducer being placed under tension and the other under compression in response to precession of the gyro rotor in the opposite direction; and, electrical means coupled to said transducers for vibrating the transducers at their natural frequency and producing a frequency proportional to the precession of the gyro motor.

2. An evacuated vibrating beam transducer capsule comprising a container (238) divided into two longitudinally spaced compartments having open outer ends, a flexible diaphragm (242, 244) sealing off each open end of said container so that said compartments can be evacuated, a vibrating beam transducer (246, 248) positioned longitudinally in each of said compartments and connected between the diaphragm thereof and a point on the wall of the container opposite said diaphragm, flexure wire means connecting each of said diaphragm to a frame, said flexure wire means being longitudinally aligned with said vibrating beam transducers, said frame (230) extending around said container With arms (234, 236) connected to said wire means at opposite ends, whereby longitudinal movement of said container relative to said frame in one direction places on transducer in compression and the other in tension and relative movement in the opposite direction places said one transducer under tension and said other transducer under compression; and, electrical means coupled to said transducers for vibrating the transducers at their natural frequency and producing a frequency proportional to the relative movement of the frame and container.

References Cited UNITED STATES PATENTS 2,024,571 12/1935 Gent 73228 2,447,817 8/1948 Rieber 25036 2,513,678 7/1950 Rieber 73--141 2,543,020 2/1951 Hess 73228 2,601,678 6/1952 Beatty 73228 3,062,052 11/1962 Kolb 73-398 3,057,208 10/1962 Bedford 73-5l7 3,190,129 6/1965 Kritz et a1. 735l7 3,238,789 3/1966 Erdley 73l41 JAMES J. GILL, Primary Examiner H. GOLDSTEIN, Assistant Examiner U.S. Cl. X.R. 745.4 

